DE3506063A1 - FLUID COMPRESSOR WITH A DEVICE FOR DETECTING THE SPEED - Google Patents

Description

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Fluid compressor with a device for detecting the speed

DESCRIPTION

The invention relates to a compressor for a vehicle air conditioning system with a device for detecting the speed.

In the case of a vehicle air conditioning compressor, if its rotation is stopped by blocking, e.g. by winding, the connection between the drive source and the compressor can be severed quickly. When the compressor an alternator and other equipment are driven together by a V-shaped belt, it is necessary to that the movement of the other equipment is not affected by the stopping of the compressor. Because of this need Speed detection devices must be coupled to the vehicle compressor.

It is well known that there are various types of rotation number detection devices for use in a compressor, e.g. mechanical types, generator types, electromagnetic types Induction types, etc. These typical speed detectors are either placed in front of the coupling or protrude from the rear of the compressor, whereby the space required for the compressor is increased. But there is the space available for a vehicle air conditioning system is limited, it is difficult to use such a speed detection device to attach.

Furthermore, a new method for detecting the speed in compressors of the type in which a main shaft does not fit through the rear of the compressor housing. E.g. in a scroll compressor the Main shaft does not go through the rear of the compressor housing, so that the speed of such a compressor does not can be detected at the rear end of the shaft, which is disposed within the housing.

The object of the invention is to provide a compressor with a device to detect the speed, which is mounted inside the compressor, to provide so that the dimensions of the compressor cannot be enlarged.

The invention is directed to a fluid compressor. Of the The compressor has a housing, a main drive shaft which is rotatably supported in the housing, and an electromagnetic one Coupling attached to the compressor housing for selectively coupling the main drive shaft to an external drive source. A compression element is driving coupled to the main drive shaft, and an asymmetrical rotating part is arranged in the housing and with the main drive shaft for rotating movement and for absorbing the magnetic flux coming from the electromagnetic Coupling is spread, coupled via the main drive shaft. A detection device detects the number of Revolutions of the compressor element. The detection device has a magnetic pickup connected to the housing and has a portion adjacent to the center of rotation the asymmetrical rotating part to accommodate the variations in the magnetic flux when the asymmetrical Rotary part is rotated past the magnetic pickup, is attached.

Further features and usefulnesses of the invention emerge from the description of an exemplary embodiment of the figures. From the figures show:

Fig. 1 is a sectional view of a scroll compressor of an embodiment of the invention;

Fig. 2 is a sectional view of a magnetic pickup used in the embodiment of the invention will;

Fig. 3 is a view of an asymmetrical rotor and a magnetic pickup, which the electromagnet

represents the induction operation of the invention;

FIG. 4 is a view showing the change in voltage produced in the magnetic pickup in FIG will;

Fig. 5 is a sectional view of a compressor of another embodiment of the invention.

Referring to the drawings, FIG. 1 shows a scroll compressor with a housing 1, which has a front plate 11 and a cup-shaped part 12, is shown. A hole 111 is incorporated in the front plate 11 and a main drive shaft 2 protrudes into the bore 111, a disk rotor 21 is on attached to the inner end of the main drive shaft 2 and rotatably supported by a bearing 13 in the bore 111.

The front plate 11 has a sleeve 14 that extends from this

protrudes and surrounds the main drive shaft 2. A warehouse 15

is mounted in the front end of the sleeve 14 for rotatably supporting the main drive shaft 2.

A clutch rotor 31 is rotatably supported by a bearing 16 and an electromagnet 32 is on the outer surface of the Sleeve 14 attached. An anchor plate 33 is elastic at the end of the main drive shaft 2 that protrudes from the sleeve 14, stored. An electromagnetic clutch thus has a clutch rotor 31, an electromagnet 32 and a Anchor plate 33 on. The rotary movement of the external drive shaft (e.g. a vehicle engine) is via the electromagnetic Transfer clutch to main drive shaft 2. In particular, the rotary motion is transmitted from the external drive source to the clutch rotor 31 via a belt; and then when the armature plate 33 is connected to the clutch rotor 31 by switching on an electrical voltage is connected to the electromagnet 32, the rotary movement from the clutch rotor 31 to the armature plate 33 and from there transmitted to the main drive shaft 2.

The opening of the cup-shaped part 12 is through the front panel 11 completed. An orbiting scroll 24 is rotatable via a bearing 23 on a drive pulley 22, which is eccentric is connected to the inner surface of the disc rotor 21, stored. A solid spiral 25 fits into the orbiting scroll 24, and the end plate of the fixed scroll 25 is attached to the cup-shaped part 12. A rotation preventing Means that prevent the rotation of the orbiting scroll 24 comprises a fixed ring 112, a circumferential ring 113 and balls 114. The fixed ring 112 is attached to the front plate 11, and the circumferential ring 113 is attached to the end plate of the orbiting scroll 24 and faces the fixed ring 112. The balls 114 are located between the two rings and held in ball receiving holes of each ring.

The fluid entering the suction port 4 is in a closed space brought by the revolving spiral ο

24 and the solid spiral 25 is formed, gradually compressed, moved to the center of the two spirals by the orbiting motion of the orbiting spiral 24, Flowed out of the outlet opening 51 to the outflow chamber 5 and supplied to the circuit via the outflow opening 6 .

A half-disk-shaped counterweight 26, which consists of a magnetic Substance is formed is with the drive device at a point between the disk rotor 21 and of the drive pulley 22, in particular the counterweight 26 is attached to the drive pulley 22.

Referring to Fig. 2, the structure of a magnetic pickup 7 according to the invention is shown. The magnetic pick-up 7 has a coil 73 which is held in a core 72. An iron core 71 is inserted through the center of the core 72. The coil 73 is mounted on the core 72, and the core 72 is attached to the iron core 71 by epoxy resin 74. The magnetic pickup 7 is inserted into the through hole through the faceplate 11 in the direction of the arrow in FIG. The through hole is preformed in the front panel 11. The distal end of the iron core 71 is shaped so that it is substantially adapted to the inner surface of the front plate 11 with which it terminates.

Referring to Fig. 3, the operation of the speed detection device will be described below explained:

When the electromagnet 32 is switched on by an electrical voltage, the main drive shaft 2 is through the The magnetic flux leakage is magnetized, and the half-disk counterweight 26 is also magnetized. Although the counterweight 26 moves with the rotation of the drive

.9 ·

Washer 22 moves, the movement of the counterweight 26 is the same as the rotational movement about the center 28 of the main shaft 12, since the drive pulley 22 is eccentrically coupled to the main drive shaft 2 via a driving mandrel. Of the Drive mandrel 22 is coupled to orbiting scroll 24 in such a manner that each rotation of the drive pulley 22 / counterweight 26 results in a complete revolution of the orbiting scroll 24. The far end of the magnetic The transducer 7 is arranged adjacent to the counterweight 26 and opposite its center of rotation, i.e. adjacent the outermost area in which the counterweight 26 rotates.

The magnetic flux (0) flowing through the magnetic pickup 7, since the half-disk counterweight 26 is magnetized, has a high level when the ABA ¹ part of the half-disk counterweight 26 comes close to the magnetic pickup 7 and has a low level when this part is not in the vicinity of the magnetic pickup 7. As a result, the magnetic flux flowing through the magnetic pickup 7 changes by the rotation of the half-disk counterweight 26, and the voltage expressed by the following formula (1) is generated in the magnetic pickup 7 by electromagnetic induction.

d 0
e = - (1)

d t

When the half-disk counterweight 26 shown in Fig. 3 rotates in the direction of the arrow, the magnetic flux (0) flowing through the magnetic pickup 7 is reduced when the point A ¹ passes the pickup 7 and one positive voltage is calculated according to formula (1) in the mag-

netic transducer 7 generated. Similarly, a negative voltage is generated in the transducer 7 when the point A passes this one. This means every time the half-disk-shaped counterweight 26 made one revolution has a positive voltage pulse and a negative voltage pulse as shown in Fig. 4 in the magnetic pickup 7 generated. Accordingly, when the number of pulses is measured, the compressor speed can be detected will. The counterweight acts due to its half-disk shape 26 as an asymmetrical rotating part, which generates electrical impulses in the transducer 7, which in relation to the rotation / Rotating the spiral 24 of the compressor element are set.

Fig. 5 shows an embodiment of the invention in which the magnetic pickup 7 is included in the swash plate compressor is. An eccentric rotor 8, one surface of which is inclined, is driven by the rotation of the main drive shaft 2 rotated. A piston 10 is swashed with a swash plate 9 that coincides with the inclined plane of the eccentric rotor 8 connected, moved up and down.

A projection 81 protrudes radially from the outer circumference of the eccentric rotor 8. The projection 81 extends around part of the circumference of the eccentric rotor 8, so that it has end points which are similar to the end points A and A ^{1 of} the counterweight 26. The eccentric rotor 8 is thus asymmetrical and works as an asymmetrical rotating part so that the magnetic flux received by the transducer 7 varies in the same way during the rotation of the eccentric rotor 8 as during the rotation of the counterweight

26. Of course, the magnetic flux in the eccentric rotor 8 results from the scattering of the magnetic flux, when the solenoid 32 is on. The rotation

of the compressor drive is in this embodiment detected in a manner similar to that of the first embodiment in which a magnetic pickup is adjacent the rotating asymmetrical part is arranged in the compressor housing.

As mentioned above, the fluid compressor according to the invention is equipped with an asymmetrical rotating part which is substantially magnetized by an electromagnetic clutch, and a magnetic pickup is adjacent the center of rotation of the asymmetrical rotation part arranged in the compressor housing. The magnetic flux that flowing through the magnetic pickup is determined by the fundamental change in the distance between the parts of the asymmetrical part and the magnetic pick-up changed. The rotation of the compression element of the compressor can can thus be detected by measuring the voltage generated by the magnetic pickup. Thus is a big one Space for a sensor in the compressor is not required and it is easy to mount in a vehicle. The speed of the compressor can be detected very precisely because the number of output pulses emitted by the magnetic pick-up which corresponds to the rotation of the main shaft.

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Claims (6)

pn PATENTANWALT DIPL.-PHYS. LUTZ H. PRÜFER · D-8OOO MÜNCHEN AG 56-3362 P / Ka / so Sanden Corporation, Isesaki / Japan Fluid compressor with a device for detecting the speed 1. Fluid compressor with a housing, a main drive shaft which is rotatably mounted in the housing, an electro magnetic coupling that is attached to the compressor housing for selectively coupling the main drive shaft to the external drive shaft is attached, a compressor element which is drivingly coupled to the main drive shaft, characterized by an asymmetrical rotating part which is arranged in the housing and rotatable with the main drive shaft and to absorb the magnetic flux that is scattered from the electromagnetic clutch over the drive shaft is coupled and a detection device for detecting the speed of the compressor element, wherein the detection PATENT ADVOCATE DIPL.-PHYS. LUTZ H. PRÜFER ■ D-8000 MUNICH 90 HARTHAUSER STR. 25d TEL. (O 89) 640 640 f Sungseinrichtung a magnetic pickup which is connected to the housing and has a part that is adjacent the center of rotation of the asymmetrical rotation part for absorbing the variation of the magnetic flux when the asymmetrical rotating part rotates past the magnetic pickup, is arranged. 2. Fluid compressor according to claim 1, characterized in that the asymmetrical rotating part is a counterweight for balancing the centrifugal force of the dre parts of the compressor. 3. Fluid compressor according to claim 2, characterized in that the compressor is a spiral compressor ter. 4. fluid compressor according to claim 1, characterized in that the asymmetrical rotating part is an eccentric rotor. 5. fluid compressor according to claim 4, characterized in that the compressor is a swash plate compressor is. 6. Fluid compressor with a compression element, which is arranged in a compressor housing, and is driven by the rotary movement of a main drive shaft, which is selectively coupled to an external drive source via an electromagnetic clutch, and an asymmetrical rotating part, which is arranged in the housing and with is connected to the main drive shaft and absorbs the magnetic flux that is scattered over the main drive shaft by the electromagnetic clutch,
characterized by a detection device which at least at least partially in the compressor housing to record the Speed of the compressor element is arranged, the detection device having a magnetic pick-up with is connected to the housing and has a part which is adjacent to the rotation center of the asymmetrical rotation part for detecting the vatiation of the magnetic flux when the asymmetrical rotating part rotates past the magnetic pickup is, is arranged.